Photovoltaic modules

ABSTRACT

A modular photovoltaic (PV) system can include a PV cell, a frame coupled to the PV cell, and a converter. The frame is configured to support a plurality of pairs of externally accessible connectors, each pair having a positive voltage connector and a negative voltage connector, the positive voltage connector of each pair of the plurality electrically connected to each other and the negative voltage connector of each pair of the plurality electrically connected to each other. The converter is configured to receive voltage from the PV cell and change the voltage for output at one or more pairs of the externally accessible connectors. The converter may include Maximum Power Point Tracking services to manage the power output from the PV cell. Multiple PV systems may be connected to each other in coplanar and non-coplanar relationships. In some embodiments, the frames have triangular, rectangular, or other polygonal shapes.

BACKGROUND

Photovoltaic (PV) cells, commonly known as solar cells, are devices forconversion of solar radiation into electrical energy. Generally, solarradiation impinging on the surface of, and entering into, the substrateof a solar cell creates electron and hole pairs in the bulk of thesubstrate. The electron and hole pairs migrate to p-doped and n-dopedregions in the substrate, thereby creating a voltage differentialbetween the doped regions. The doped regions are connected to theconductive regions on the solar cell to direct an electrical currentfrom the cell to an external circuit. When PV cells are combined in anarray such as a PV device, the electrical energy collected from all ofthe PV cells can be combined in series and parallel arrangements toprovide power with a certain voltage and current. The arrays may then beincorporated into energy products for end users.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an exemplary photovoltaic (PV) module according tosome embodiments.

FIG. 2 illustrates an exemplary PV module according to some embodiments.

FIG. 3 illustrates an example of two PV modules connected in a coplanarconfiguration, according to some embodiments.

FIG. 4 illustrates an example of two PV modules connected in anon-coplanar configuration, according to some embodiments.

FIG. 5 illustrates an example of the PV module of FIG. 1 coupled to twoPV modules of FIG. 2, according to some embodiments.

FIG. 6 illustrates an example of an internal electrical configuration ofa PV module, according to some embodiments.

FIG. 7 illustrates another example of an internal electricalconfiguration of a PV module, according to some embodiments.

FIG. 8 illustrates an example of three PV modules of FIG. 7 electricallycoupled in parallel, according to some embodiments.

FIG. 9 illustrates two PV modules of FIG. 6 electrically coupled inseries, according to some embodiments.

FIG. 10 illustrates the PV modules of FIG. 2 electrically coupled to abattery block, according to some embodiments.

FIG. 11 illustrates the battery block of FIG. 10 secured to the bottomof a PV module, according to some embodiments.

FIG. 12 illustrates a flowchart of an assembly process, according tosome embodiments.

DETAILED DESCRIPTION

PV devices can be used in one-dimensional arrays, where PV devices areconnected one after another into a string. PV devices can also be usedin two-dimensional arrays, where several adjacent strings are connectedside-by-side. The two-dimensional arrays may be more prevalent in largerinstallations, such as rooftops and industrial solar power plantsystems, while one-dimensional arrays may be more prevalent in smallerinstallations, such as personal powered devices, e.g., solar poweredfans, landscape lighting, and personal charging stations. Manufacture ofthese one-dimensional and two-dimensional arrays is cumbersome andinefficient as specific dimensions and operating characteristics areconsidered and tailored for each specific installation ahead of thefinal design, manufacture, and assembly. This one-off design,manufacture, and assembly process drives costs upwards and serves tolimit adaptability and deployment of solar arrays into a broad spectrumof commercial, industrial, and personal applications.

The detailed description is merely illustrative in nature and is notintended to limit the embodiments of the subject matter of theapplication or uses of such embodiments. As used herein, the word“exemplary” means “serving as an example, instance, or illustration.”Any implementation described herein as exemplary is not necessarily tobe construed as preferred or advantageous over other implementations.Furthermore, there is no intention to be bound by any expressed orimplied theory presented in the preceding technical field, background,brief summary or the following detailed description.

This specification includes references to “one embodiment” or “anembodiment.” The appearances of the phrases “in one embodiment” or “inan embodiment” do not necessarily refer to the same embodiment.Particular features, structures, or characteristics may be combined inany suitable manner consistent with this disclosure.

Terminology. The following paragraphs provide definitions and/or contextfor terms found in this disclosure (including the appended claims):

“Comprising.” This term is open-ended. As used in the appended claims,this term does not foreclose additional structure or steps.

“Configured To.” Various units or components may be described or claimedas “configured to” perform a task or tasks. In such contexts,“configured to” is used to connote structure by indicating that theunits/components include structure that performs those task or tasksduring operation. As such, the unit/component can be said to beconfigured to perform the task even when the specified unit/component isnot currently operational (e.g., is not on/active). Reciting that aunit/circuit/component is “configured to” perform one or more tasks isexpressly intended not to invoke 35 U.S.C. § 112, sixth paragraph, forthat unit/component.

“First,” “Second,” etc. As used herein, these terms are used as labelsfor nouns that they precede, and do not imply any type of ordering(e.g., spatial, temporal, logical, etc.). For example, reference to a“first” solar cell does not necessarily imply that this solar cell isthe first solar cell in a sequence; instead the term “first” is used todifferentiate this solar cell from another solar cell (e.g., a “second”solar cell).

“Based On.” As used herein, this term is used to describe one or morefactors that affect a determination. This term does not forecloseadditional factors that may affect a determination. That is, adetermination may be solely based on those factors or based, at least inpart, on those factors. Consider the phrase “determine A based on B.”While B may be a factor that affects the determination of A, such aphrase does not foreclose the determination of A from also being basedon C. In other instances, A may be determined based solely on B.

“Coupled”—The following description refers to elements or nodes orfeatures being “coupled” together. As used herein, unless expresslystated otherwise, “coupled” means that onecomponent/element/node/feature is directly or indirectly joined to (ordirectly or indirectly communicates with) anothercomponent/element/node/feature, and not necessarily mechanically.

In addition, certain terminology may also be used in the followingdescription for the purpose of reference only, and thus are not intendedto be limiting. For example, terms such as “upper”, “lower”, “above”,and “below” refer to directions in the drawings to which reference ismade. Terms such as “front”, “back”, “rear”, “side”, “outboard”, and“inboard” describe the orientation and/or location of portions of thecomponent within a consistent but arbitrary frame of reference which ismade clear by reference to the text and the associated drawingsdescribing the component under discussion. Such terminology may includethe words specifically mentioned above, derivatives thereof, and wordsof similar import.

In the following description, numerous specific details are set forth,such as specific operations, in order to provide a thoroughunderstanding of embodiments of the present disclosure. It will beapparent to one skilled in the art that embodiments of the presentdisclosure may be practiced without these specific details. In otherinstances, well-known techniques are not described in detail in order tonot unnecessarily obscure embodiments of the present disclosure.

This specification includes a description of exemplary photovoltaic (PV)modules, which may comprise one or more PV cells supported by a frameand, possibly, a DC voltage conversion circuit of some kind. This PVcell, frame and possible conversion circuit, as well as processes ofmanufacture, and processes of assembly involving them, are describedherein in various combinations and with various features. Thesecombinations and features are illustrative and may be combined withother features and processes. Thus, the descriptions provided areexemplary and not intended to limit the full aspects of the inventionand how it may be embodied, to those embodiments specificallyillustrated and described herein.

Embodiments may provide a modular PV building block system where PVmodules may be physically and electrically coupled in variousconfigurations. The configurations can be suitable for variousapplications and may provide various outputs and management topologies.Configurations of PV modules may be permanent and may also bereconfigurable, such that connected PV modules may be reconnected in thesame orientation or a different orientation after being initiallyconnected. A PV module of these building-block type systems may includeone or more PV cells as well as a supporting frame. These cells andframes may be assembled in various configurations to meet spacerequirements of a target installation as well as voltage or otherelectrical output requirements of a target installation. For example,0.6 VDC and 1.2 VDC and 3.0 VDC modules may be combined in various waysto meet a 6.0 VDC output target.

The modules may also include a voltage management circuit as well. Thesevoltage management circuits may provide converter and/or inverterservices and functionality for a PV module as well as a grouping ofconnected PV modules. When a converter circuit is employed inembodiments, the circuit may serve to change output voltage of one ormore PV cells of a PV module for subsequent use. Similarly, theconverter circuit may also service several PV modules, more like acentral converter or inverter.

As noted above, various overall combinations may be assembled using themodular frame and PV cell building block system described herein. Forexample, a first rectangular frame supporting eight PV cells, i.e., afirst module, may be coupled to a second rectangular frame, which alsosupports eight PV cells, i.e., a second module. Because of thedimensions of the frames, the overall system of sixteen PV cells mayhave a square configuration if long dimensions of the rectangular framesare adjacent. Conversely, if the short ends of the frames are coupled,the overall resulting system remains a rectangle and will be twice aslong as either frame before the frames were coupled. Under this modularsystem, numerous numbers of system shapes and sizes can be made fromassembling modules of PV cells and frames together.

The PV modules of embodiments may have various shapes, includingrectangular, square, circular, triangular, oval, and numerous polygons.This building block scheme for PV modules can enable PV modules to becoupled together to accommodate power demands of a final application,physical shape and/or size requirements of a final application, and forother reasons as well. For example, if a 7.2 VDC 24 Watt output isrequired to power a hand-held fan, twelve 0.6 VDC modules may beconnected together and attached to a converter circuit for managingelectrical output to the fan. Similarly, 1.2 VDC modules may beconnected to 0.6 VDC modules as well to reach the 7.2 VDC target. Otherconnections and groupings may also be conducted, where target voltagesare achieved through other module groupings as well as with or solelyusing downstream conversion circuits. Still further, the combination ofcells and converters can be variously configured, using PV modules ofdifferent shapes, sizes, outputs, and configurations, to addressvoltage, power, cost, size, and other metrics and provide an optimumsolution. For example, space may be optimized by using oval PV modulesin near oval applications and power can be optimized by combining PVmodules with different power characteristics to fit a certain targetlocation.

PV Module connection may occur during assembly of a fan, by amanufacturer of the fan who did not special order PV cells for thespecific fan application, but had many various PV modules in stock andready for use in different products. This manufacturer may select fromits stock of PV modules in order to finish assembly or manufacture ofits fan product through the use of stock PV modules that were not,necessarily specially designed for use in the fan application. Thus,embodiments, can provide flexibility for manufacturers or others totailor PV module combinations to specific applications for which aspecific PV module or modules were not specifically designed for or whenstand-alone specific PV cells were not thought to be readily in stock.

As noted, this flexibility of design can include flexibility inelectrical output as well as size and shape. PV module kits can beprovided where numerous different sizes and shapes and outputs of PFmodules are provided and a user may then select the combination ofsizes, shapes, and outputs to suit his or her needs. This ability toassemble, through the connection and switch features described herein,may allow embodiments to be employed in a first application and thenredeployed in a second application after the first use was no longerpreferred. For example, an assembly of six PV modules, including sixframes and PV cells within those frames and one DC converter may beemployed to power outdoor patio lights for several years. Then, when thehomeowner moves or wishes to use the PV modules for a different purpose,the modular system may be deconstructed and assembled in a differentcombination for a different use. This modularity in assembly and abilityto deconstruct and reuse may provide flexibility and prolong theusefulness of each frame and PV cell(s).

Still further, the modularity of embodiments may provide for placementof PV cells in unusual locations or in unusual shapes. For example, if asemi-circle cap of a hat is a target location for PV power, to provideelectrical power for lights or a fan, the modularity of severaltriangular shaped PV modules may be employed to encircle the rim of acap and provide power to the intended load. This flexibility of shapemay apply in larger designs as well. For example, solar-poweredvehicles, having aerodynamic shapes, may employ combinations ofpolygons, circles, and ellipses to cover the vehicle. Various otherapplications where both shape and power output specialization need beemployed in short turn-around times or with minimal specialized design,can benefit from and employ PV modules in accord with embodiments.

In some embodiments, the connectors between each PV module may be biasedto prevent detachment and/or to promote proper connection. When theconnectors are biased against detachment, a deconnector pin or otherarrangement may be used to retard unwanted disconnection of theconnectors. In other words, a connector may have a male pin and a femalereceiver that accepts the pin and allows the pin to snap into thereceiver when the connector is properly seated. To disconnect theconnectors the pin may need to be pushed out of the female receiverbefore the connectors can be slid apart. Proper connection may beprovided through orientation tabs to prevent connection of positive andnegative connectors or other unwanted connections. These orientationtabs may use friction, specific shape, and other features to promoteproper connections and render improper connections impossible.

As noted, PV modules of embodiments may contain a supporting frame andone or more PV cells. This combination may have the frame surroundingthe cells and defining the perimeter of the module. The frame may alsobe at other locations relative to the cell(s). For example, the framemay be on two perimeters of a rectangular PV module and below two of theother perimeters of the rectangle. Similarly, if the PV module is in theshape of a circle, the frame may be along the circumference of thecircle or may be within the circle as well. Moreover, the frame does notneed to mimic the shape of the module. For example, a rectangular frameor a frame in the shape of an X can be supporting PV cells having acircular perimeter.

In embodiments, connectors are preferably accessible and uniformlyspaced on each perimeter side of the PV module. Also, the connectorspreferably extend out from the PV module such that two PV modules can beconnected side-by-side with little or no space between them. However, asshown in FIG. 4, a space may exist between PV modules when the modulesare connected.

PV modules of embodiments may include inverters or converters or otherpower management circuits to change the output of the individual PVmodules or a group of modules. Inverters and converters, as well asother power management circuits, may also be employed to serve agrouping of modules rather than only on a one-on-one basis, e.g., oneconverter for one PV module.

Individual PV modules and combinations of them may be encapsulated forenvironmental protection. This encapsulation may surround each PV moduleas well as groupings of PV modules. The encapsulation may serve toprotect the PV cell(s), frame, and any power management circuitry fromenvironmental impacts or other external forces. Encapsulation may alsobe performed after assembly and connections have been made to protectthe connections, hold the PV modules in place, encapsulate unusedconnectors, shield unused connectors, and for other reasons as well. Forexample, two PV modules connected by traces and positioned in anon-planar fashion may be connected, then secured in place with epoxy,and then encapsulated in a potting material with only the PV cell(s)exposed in their final installation position. A manufacturer may conductthese encapsulation steps or others when incorporating PV modules ofembodiments into a product or other item of manufacture.

As noted above, the modular flexibility may allow for converters or PVcells with different outputs to be connected together to reach a targetpower output. For example, if a 4.5 Volt AC output is desired a 1.5 VoltDC and a 3.0 Volt DC PV module may be connected where either or both ofthe PV modules also contains a converter circuit for outputting the ACvoltage. This converter circuit may have various degrees of complexitywith some being uncomplicated two transistor inversion circuits whileothers may have more functionality and features, such as an H-bridge andMaximum Power Point Tracking. The converter circuit may also have boostcapabilities in embodiments. Thus, modular systems of embodiments mayinclude various shaped PV modules with different output specificationsand one or more power management circuits for each module and/or for theconnected grouping of modules. Once this grouping is connected andsecured in its final application, the modules and any circuitry may befurther covered in epoxy or silicon or other suitable material for finaluse.

FIG. 1 depicts a PV module 100 that may be used in PV modular systemsaccording to some embodiments. The PV module 100 comprises a triangularframe 102 surrounding a plurality of solar cells 104. Each side of theframe 102 supports a pair of externally accessible connectors, apositive voltage connector 106A and a negative voltage connector 106B.Internally, the positive voltage connectors 106A are electricallyconnected to each other and the negative voltage connectors 106B areelectrically connected to each other. When light is reaching the solarcells 104 a voltage V_(A-B) is present across the connectors 106A, 106B.Although referred here as a plurality of solar cells 104, in someembodiments, the plurality of solar cells 104 can be one solar cell.

FIG. 2 depicts a PV module 200 that may be used in modular PV systemsaccording to some embodiments. The PV module 200 comprises a squareframe 202 surrounding a plurality of solar cells 204. Each side of theframe 202 supports a pair of externally accessible connectors, apositive voltage connector 206C and a negative voltage connector 206D.The positive voltage connectors 206C may be electrically coupled to eachother and the negative voltage connectors 206D may be electricallycoupled to each other. As shown in subsequent figures, the connectionsof connectors C and D may be severed such that only one side or twosides or three sides can provide a voltage while the other nonconnectedand now severed side can no longer provide a voltage. When light isreaching the solar cells 204 a voltage V_(C-D) is present across theconnectors 206C, 206D. Although referred here as a plurality of solarcells 204, in some embodiments, the plurality of solar cells 204 can beone solar cell.

The triangle and square frames 102, 202 of the embodiments illustratedin FIGS. 1 and 2 are just two of the possible shapes in which PV systemsof the present invention may be formed and are representative ofpolygonal frames in general that may be incorporated into PV systems,according to embodiments. The illustrated and described PV systems 100,200 are likewise representative, regardless of shape or internal orexternal electrical configuration. In an example, the frames 102, 202can be circular, rectangular, trapezoidal, or any other polygonal frameshape.

In addition to providing electrical connections to the solar cells ofthe PV modules, the positive and negative connectors may also providemechanical connections to other PV modules to form a PV array or device.To facilitate building block type connection layouts, the distancebetween the positive and negative connectors of each pair of connectorson each side is preferably uniform or the same. For example, thedistance between the positive and negative connectors 106A, 106B of eachof the three pairs of connectors of the PV module 100 is the same as thedistance between the positive and negative connectors 206C, 206D of eachof the four pairs of connectors of the PV module 200. Thus, two (ormore) PV modules may be electrically and mechanically coupled in variousways and between various sides. If a frame or PV cell topology iscircular or oval or otherwise lacks a straight side, the connectors maynevertheless be positioned by arms or extenders from the frame to theproper uniform location for connection to another module. In so doing,circular, oval and other nonlinear PV modules may be, nevertheless,coupled to a linear side of a PV module or even a PV module without anylinear sides as well.

FIG. 3 illustrates two PV modules 100 and 200 that are mechanically andelectrically coupled in the same plane. Each of the connectors 106A,106B on one side of the frame 102 comprises a first side 210A of a hookor snap and each of the connectors 206C, 206D on one side of the frame202 comprises a second side 210B of the hook or snap. The first andsecond sides 210A, 210B of the hook or snap are interlocking orotherwise matable with each other, as illustrated in the enlargedportion of FIG. 3, providing a preferably secure physical connectionbetween the two PV modules 100, 200. Other means may be provided tomechanically and electrically couple the connectors of adjacent PVsystems. However, a system, such as the hook or snap system illustratedin FIG. 3, provides a quick, tool-free method of assembling multiple PVcells into an array. And, if desired, the array may be disassembled byreversing the assembly process. A rigid backing 112, 212 may enhance thestructural integrity of each PV system 100, 200. Moreover, the rigidbacking 112, 212 may provide support for and protection to an overlyingarray of PV cells.

PV modules 100, 200 may also be coupled in a non-coplanar configuration,as illustrated in FIG. 4. Instead of rigid connectors such as thehook/snap 210A, 210B of FIG. 3, PV modules may be coupled using flexibleor hinge-like connectors 214. Such a configuration is beneficial when anarray of PV modules is mounted on or integrated into such items asclothing or backpacks, for example, allowing the array to flex withmotion of the underlying item. The flexible connectors may beelectrically conductive hinges or may be formed from electrical tracesor bare conductors having sufficient strength to withstand repeatedbending without breaking.

Due to the many applications for solar power, no single arrayconfiguration will accommodate every application. Therefore, differentshapes of the PV modules represented by the PV modules 100, 200 may becoupled together to form arrays or devices in a variety of other, largershapes and sizes. FIG. 5 illustrates an example of the triangular PVmodule 100 coupled to two square PV modules 200. It will be appreciatedthat other combinations will form other shapes, allowing PV arrays ordevices to be made to accommodate many different applications. Theconnection paths for the connectors of FIGS. 6-10 are also visible. Ascan be seen, the positive and negative connectors for each side aresuitable for connection to one another. FIGS. 6-10 also show that a cellconverter 608, 708 may be coupled to these connectors and the internallines of the PV modules.

When a number of PV modules of embodiments are coupled together in aone-dimensional or two-dimensional array, they may not all have the sameorientation relative to the sun or, because of differences in size, maynot all receive the same amount of light. In some circumstances, somemay even be in shade while others receive sunlight. Thus, differentsolar cells in the array may have different voltages and currents attheir respective output connectors and one or more cells may operateaway from maximum power. A power converter (cell converter) may beembedded in the individual PV module according to embodiments. The cellconverter may be, for example, a DC-DC boost converter to raise therelatively low voltage output from a solar cell, such as 0.6 V, to amore useful voltage, such as 1.1 V for logic circuitry, 3.3 V for analogor logic circuitry, 5.0 V for USB compatibility, or other voltages asrequired. Other types of converters and inverters may also be used.

Each cell converter preferably incorporates a maximum power pointtracking (MPPT) function enabling each cell converter to provide themaximum possible power at the output connectors. Under conditions inwhich the load is unable to absorb all of the available power, the cellconverter may sense the over-voltage and reduce the power output tomatch the load. Also, power may be curtailed until the voltage drops toa compatible level or the converter may use a control loop to reducepower to a level required to maintain a desired voltage.

FIGS. 6 and 7 illustrate different internal configurations by which acell converter 608, 708 may be electrically coupled to the positive andnegative connectors. FIG. 6 illustrates the PV module 600 in which thepositive and negative connectors 606A, 606B are positioned alternatelyaround the perimeter of the frame 602 and electrically coupled to thecell converter 608. FIG. 7 illustrates the PV module 700 in which thepositive and negative connectors 706A, 706B on one side of the frame 702are reflected by the positive and negative connectors 706A, 706B on theopposite side and electrically coupled to the cell converter 708.

The selection of the configuration of positive and negative connectors,FIG. 6 or FIG. 7, is preferably selected using the particularapplication for which the PV system is to be used. Likewise, the voltageat the cumulative output of the PV modules of the array is generallybased on other components to which the array of modules is coupled. Forexample, FIG. 8 illustrates an example of three PV modules 700 of FIG. 7electrically coupled in parallel configured to increase the power outputto a voltage bus V_(bus), according to some embodiments.

FIG. 9 illustrates an example of two PV modules 600 of FIG. 6electrically coupled in series configured to increase the voltageoutput, being the sum of the voltages, i.e., 625,626, of the individualPV modules 600, to the voltage bus V_(bus), according to someembodiments. Any or all of the cell converters and/or internal lines ofembodiments may include an internal disconnect 610, such as a switch,fuse, or the like, to deactivate one or more of the cell converter'spositive external voltage connections, negative external voltageconnections, or both, thus enabling the PV modules to be connected inseries, as shown. Also, to prevent physical, and therefore electrical,contact with external connectors of other PV systems, one or more of theexternal voltage connectors of embodiments may be configured to beremoved, such as by tearing or cutting, from the frame. One or more ofthe external voltage connectors may also be capped or otherwise covered.

In embodiments, the positive and negative connectors may be notched,keyed, indexed, or otherwise prevented from being electricallyincorrectly coupled with each other. For example, the connectors of PVmodule 700 illustrated in FIG. 7 may be indexed such that the positiveconnectors will mate with positive connectors and negative connectorswill mate with negative connectors to allow the PV module 700 to becoupled in parallel (FIG. 8). And, the connectors of PV module 600illustrated in FIG. 6 may be indexed such that the positive connectorswill mate with negative connectors to allow the PV module 600 to becoupled in series (FIG. 9).

Embodiments may also include a storage cell 1000 electrically coupled toone of the pairs of externally accessible connectors of a PV module 700,as illustrated in FIG. 10. The storage cell 1000 may be a battery or acapacitor and may include power converter 1002. To allow for chargingthe storage cell 1000 from the PV module 700 and discharging the storagecell 1000 to a connected load when there is insufficient power from thePV module 700, the power converter 1002 or other converters inembodiments may be bi-directional. For example, a synchronous buckconverter may be used to step down the voltage from the bus V_(bus) tothe storage cell 1000 and step up the voltage from the storage cell 1000to the bus. The power converter 1002 monitors the bus voltage andincreases or decreases the current to the storage cell 1000 to maintainthe bus voltage. An example of such a bi-directional converter 1002 isdescribed in U.S. Pat. No. 8,350,411, entitled Modular System forUnattended Energy Generation and Storage, assigned to the assigneehereof and incorporated by reference in its entirety.

The energy storage capability of the storage cell 1000 and its voltageand current characteristics, among other characteristics, may beselected to accommodate desired applications. The storage cell 1000 maybe only electrically coupled to the PV module 700, such as with wire.Alternatively, the storage cell 1000 may also be physically secured tothe PV module 700, such as with the hooks 210A, 210B illustrated in FIG.3.

FIG. 11 depicts the storage cell 1000 secured below the PV module 700,forming a compact unit. Although in some embodiments, every PV module700 may be electrically (and possibly mechanically) coupled to a storagecell 1000, in other embodiments, there may be fewer storage cells 1000than PV modules 700, all based upon the desired application. In stillother embodiments, the load connected to the array itself may serve asan energy storage unit, such as a mobile phone with its own internalbattery. Rather than include MPPT capability, the power converter 1002may regulate the output voltage to accommodate the battery in the load.

When a number of storage cells 1000 are incorporated into an array, oneor more storage cells 1000 may discharge before the others, reducing itscycle life. A controller that allows power to be shared among thestorage cells 1000 and allows them to discharge equally is the subjectof U.S. Pat. No. 7,663,342, entitled Apparatus, System, and Method forControlling Multiple Power Supplies, assigned to the assignee hereof andincorporated by reference in its entirety. Such a controller maycomprise the controller 1002.

In some instances, the bus voltage from the array is incompatible withthe load requirement. A post-regulator, such as any of various designsof linear and switching regulators, may be used to provide one or moreadditional voltage outputs.

After PV systems and storage cells are assembled into a desiredconfiguration, the resulting array or device may be electrically coupledto the load with any appropriate output connector 1020 (FIG. 10) andcable. One end of the cable connects to the array and the connector 1020on the other end is connectable to the load, either permanently orremovably, such as when a USB connector is used.

In some embodiments, the surface of a PV module may have a color and thesurfaces of different PV systems in an array may have different colors,allowing various aesthetic patterns and effects to be created. Thesurface of the PV system may also be etched with designs or text.

PV modules (referring generally to the PV modules according toembodiments regardless of shape or internal electrical configuration)may be fabricated in a number of sizes and shapes and sold to developersto be assembled and incorporated into specific products for end users.Turning now to the flowchart of FIG. 12, an exemplary process will bedescribed for the assembly of PV modules into an array or device by adeveloper (or by the manufacturer). For each application for which thedeveloper wishes to provide a PV array (step 1200), the developer willpreferably calculate the power requirements for the item to which thearray will be coupled (step 1202) and the number, sizes, and shapes ofthe PV modules 100 to generate the desired power output (step 1204). Theinternal electrical configuration of each PV module may also bedetermined (step 1206). Some or all of the PV modules may be coupled inparallel (step 1208) while some or all may be coupled in series (step1210). If some are to be coupled in series, an internal disconnect maybe provided (step 1212), such as the disconnect 610 illustrated in FIG.9 and described above. The developer may also determine the physicalarrangement of the PV module 100 (step 1214). If part or all of thearray or device will be coplanar (step 1216), the PV module maypreferably have rigid connectors (step 1218), such as the connector210A, 210B illustrated in FIG. 3 and described above. If part or all ofthe array or device may be non-coplanar (step 1220), the PV modules maypreferably have flexible connectors (step 1222), such as the connector214 illustrated in FIG. 4 and described above.

If the electrical item to which the array is to be electrically coupledincludes an internal battery (step 1224), such as a cell phone or tabletcomputer, it is not necessary that the PV module the developer selectsinclude storage cells 1000. If, however, the array is intended toprovide power to an electrical item without an internal battery, atleast some of the PV modules will include a storage cell 1000 and thedeveloper determines the number and capacity of the storage cells 1000(step 1226). The developer may then secure the storage cells 1000 to thePV modules, as illustrated in FIG. 11, or electrically couple themtogether if a mechanical connection is not necessary (step 1228). Theresulting units of PV modules and storage cells 1000 are then assembledinto the array (step 1230). Finally, the developer selects a connector1020 that is compatible with the electrical item to be powered orcharged (step 1232) and attaches a cable between the positive andnegative connectors of the array and the connector 1020 (step 1234).

Although specific embodiments have been described above, theseembodiments are not intended to limit the scope of the presentdisclosure, even where only a single embodiment is described withrespect to a particular feature. Examples of features provided in thedisclosure are intended to be illustrative rather than restrictiveunless stated otherwise. The above description is intended to cover suchalternatives, modifications, and equivalents as would be apparent to aperson skilled in the art having the benefit of this disclosure.

The scope of the present disclosure includes any feature or combinationof features disclosed herein (either explicitly or implicitly), or anygeneralization thereof, whether or not it mitigates any or all of theproblems addressed herein. Accordingly, new claims may be formulatedduring prosecution of this application (or an application claimingpriority thereto) to any such combination of features. In particular,with reference to the appended claims, features from dependent claimsmay be combined with those of the independent claims and features fromrespective independent claims may be combined in any appropriate mannerand not merely in the specific combinations enumerated in the appendedclaims.

What is claimed is:
 1. A modular photovoltaic system comprising: aphotovoltaic (PV) cell; a first frame coupled to the PV cell, the firstframe configured to support a plurality of pairs of externallyaccessible connectors, each pair of the plurality having a positivevoltage connector and a negative voltage connector, the positive voltageconnector of each pair of the plurality electrically connected to eachother and the negative voltage connector of each pair of the pluralityelectrically connected to each other, each pair of the plurality ofpairs of externally accessible connectors extending outwardly from thefirst frame; and a converter configured to receive voltage from the PVcell and change the voltage for output at one or more pairs of theexternally accessible connectors.
 2. The modular photovoltaic system ofclaim 1 wherein the PV cell consists of a triangular shape and the firstframe consists of three connected sides.
 3. The modular photovoltaicsystem of claim 1 further comprising a second frame, the second framecoupled to a second PV cell, the second frame configured to support aplurality of pairs of externally accessible connectors, each pair of theplurality of pairs of externally accessible connectors having a positivevoltage connector and a negative voltage connector, the positive voltageconnector of each pair of the plurality of pairs of externallyaccessible connectors electrically connected to each other and thenegative voltage connector of each pair of the plurality of pairs ofexternally accessible connectors electrically connected to each other,each pair of the plurality of pairs of externally accessible connectorsextending outwardly from the second frame, wherein when a pair ofexternally accessible connectors from the first frame and from thesecond frame are connected the first frame and the second frame arespaced apart from each other.
 4. The modular photovoltaic system ofclaim 1 wherein the pairs of externally accessible connectors are biasedto promote connection orientation to pairs of externally accessibleconnectors supported by a second frame.
 5. The modular photovoltaicsystem of claim 1 further comprising: a storage cell, the storage cellpositioned outside of the first frame; and a storage cell converter, thestorage cell converter configured to increase or decrease voltage to orfrom the storage cell.
 6. The modular photovoltaic system of claim 5wherein the storage cell is a battery or a capacitor.
 7. The modularphotovoltaic system of claim 1 wherein the converter is configured withMaximum Power Point Tracking services to manage power output of the PVcell, wherein the PV has an outer periphery, wherein the frame surroundsthe outer periphery of the PV cell, wherein at least one pair ofexternally accessible connectors is configured with tear-away bias, andwherein a switch is positioned to disconnect a positive voltageconnector or a negative voltage connector from a pair of externallyaccessible connectors.
 8. A modular solar cell device comprising: afirst multi-side frame configured to mate with a second multi-sideframe, the first multi-side frame surrounding at least one photovoltaic(PV) cell, the first multi-side frame supporting a plurality of pairs ofexternal connectors, wherein the pairs of external connectors havepositive and negative connectors with the positive connectors positionedaround the first multi-side frame and electrically connected to eachother via a first circuit and the negative connectors positioned aroundthe first multi-side frame and electrically coupled connected to eachother via a second circuit, the first circuit separate from the secondcircuit, an internal switch electrically coupled to at least thepositive connectors or the negative connectors such that when the switchis closed the at least one PV cell is connected in parallel to a secondPV cell outside of the first multi-side frame and when the switch isopen the at least one PV cell is connected in series to a second PV celloutside of the first multi-side frame.
 9. The modular solar cell deviceof claim 8 wherein the first multi-side frame is further configured tomate with the second multi-side frame along a shared plane of referenceand both the first multi-side frame and the second multi-side frame arein the shape of a polygon.
 10. The modular solar cell device of claim 8wherein the first multi-side frame is further configured to mate withthe second multi-side frame while not being on the same plane ofreference as the second multi-side frame and both the first multi-sideframe and the second multi-side frame are in the shape of a triangle orquadrilateral or other polygon.
 11. The modular solar cell device ofclaim 8 wherein the second multi-side frame supports and surrounds atleast one photovoltaic (PV) cell.
 12. The modular solar cell device ofclaim 8 wherein the converter is configured with Maximum Power PointTracking services to manage power output of at least one PV cell. 13.The modular solar cell device of claim 8 wherein the first multi-sideframe is further coupled to a battery, the battery configured to receiveand store voltage from at least one PV cell.
 14. The modular solar celldevice of claim 8 wherein the external connectors electrically arecoupled to a converter, the converter electrically coupled to the atleast one PV cell, and wherein the converter is configured withover-voltage management, the over-voltage management tailored to senseover-voltage conditions and curtail power in response.
 15. The modularsolar device of claim 8 wherein at least some of the external connectorsare notched, the notch providing a failure location for removing theexternal connector from connection to the multi-side frame the connectoris supported by.
 16. The modular solar device of claim 8 wherein a firstswitch is positioned and configured to electrically connect orelectrically disconnect one or more positive voltage externalconnectors, or a second switch is positioned and configured toelectrically connect or electrically disconnect one or more negativevoltage external connectors, or both.
 17. A modular solar cell devicecomprising: a first multi-side frame configured to mate with a secondmulti-side frame, the first multi-side frame surrounding at least onephotovoltaic (PV) cell, the first multi-side frame supporting aplurality of pairs of external connectors, wherein the pairs of externalconnectors have positive and negative connectors with the positiveconnectors positioned around the first multi-side frame and electricallyconnected to each other and the negative connectors positioned aroundthe first multi-side frame and electrically connected to each other, andwherein the first multi-side frame is further configured to mate withthe second multi-side frame while not being on the same plane ofreference as the second multi-side frame.
 18. The modular solar celldevice of claim 17 wherein the second multi-side frame surrounds atleast one photovoltaic (PV) cell and wherein an output voltage of thefirst multi-side frame is different than an output voltage of the secondmulti-side frame.
 19. The modular solar cell device of claim 17 whereinthe second multi-side frame surrounds at least one photovoltaic (PV)cell and wherein an output voltage of the first multi-side frame istwice or half an output voltage of the second multi-side frame.